Microsoft Word - 1murphy.docx


 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 58, 2017 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Remigio Berruto, Pietro Catania, Mariangela Vallone
Copyright © 2017, AIDIC Servizi S.r.l. 
ISBN 978-88-95608-52-5; ISSN 2283-9216 

Using Leucaena to Improve the Quality of Pineapple Plant Silage 
Wichai Suphalucksanaa*,  Settasit Sangsoponjitb, Kanokrat Srikijkasemwatc 
 

Faculty of Agricultural Technology, King Mongkut’s Institute of Technology Ladkrabang,  Bangkok, 10520, Thailand 
wichais@hotmail.com 

The objective of this study was to improve the quality of pineapple plant silage by leucaena supplementation 
and using it as roughage during the shortage of green forages. There were 5 treatments as follows :-              
1. Pineapple plant 100%, 2. pineapple plants  mixed with leucaena 5%, 3. pineapple plants mixed with 
leucaena 10%, 4. Pineapple plants mixed with leucaena 15% and 5. grass 100%. The Completely 
Randomized Design (CRD) with four replications each was used in this experiment. All treatments were put in 
1%NaCL2 and tightly sealed in plastic containers. They were stored at room temperature for 21 days. The 
silage treatments were evaluated on physical characteristics, chemical composition and fibre analysis. The 
physical characteristic showed that the color of  treatment 1 was a yellow green color, a good characteristic of 
silage. For treatments 2, 3 and 4 there was a light brown color. Treatment 5 was a dark brown in color. The 
aromas of all silage treatments were aromatic and acidic like pickled fruit. The evaluation of chemical 
composition showed a highly significant difference among the treatment groups (p <  0.01). Treatment 4 was 
the highest in protein and metabolizable energy percentage with the averages of  8.19% and 3,697.17 kcal/k, 
respectively. The percentage of crude fibre was reduced with the increase of leucaena in the silage. 
Treatment 5 was the highest in crude fibre. The pineapple plant silage mixed with leucaena  could improve the 
quality of silage  for ruminants.     
Keywords:   pineapple plant, leucaena, pineapple plant silage, ruminant feed  

1. Introduction 

Pineapple is one of  the  economic fruits of  Thailand. This product is mostly used for fresh fruit consumption 
and processing products within the country and exported in terms of canned fruits  and frozen fruits. There are 
large amounts of pineapple plant which are harvested fresh for fruit consumption and processing products 
such as canned pineapple (Gowda, 2015). Thus the farmer must dispose of this large amount of pineapple 
plant waste to alleviates this problem for a green environment. Now they try to make a value added aspect of 
pineapple and their by-products. Also, the use of pineapple plants contributes to useful material for the 
industrial sector such as textile, pineapple fibre cloth, enzyme, combustible material, etc.  
Pineapple is a component of the trunk. Farmers cut off the plants after harvesting. Pineapple leaves are waste 
or by – product of agriculture. There are almost all year long and will be much in range November – June 
because it is period when most farmers collect the yield delivered factory, which meet the drought season, 
where farmers shortage of fresh grass for ruminant. The analysis of pineapple leaves showed that the protein 
8.47 %, fibre 17.89 %, ADF 25.87% and NDF 42.28 % (Warunee and Walaikhan, 1998). Pineapple leaves can 
be used as a component in total mixed ration for dairy feed, without any effect on milk production. 
The most important aspect of animal husbandry is to reduce the costs of production or the costs of animal 
feed in order to maintain the livestock business. The reduction in production costs that can be achieved is the 
feed efficiency. Ruminants are animals that use both concentrate and roughage. Roughage include forage 
crop such as grass and legume. But roughage is usually of low quality and insufficient for the needs of 
ruminants. Because the farmers have limited space in the preparation of forage crop or pasture and often 
lacking, especially during the dry season. There are various by – products in agriculture instead such as 
pineapple leaves or pineapple plant can be used to feed dairy cattle (Prachya et al., 2001). Pineapple leaves 
or pineapple plant can be a source of roughage for ruminants, but lack of knowledge and understanding of the 
proper use, the opportunity to be used to maximum benefit. Because of this, it is necessary to develop 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1758142

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Suphalucksana W., Sangsoponjit S., Srikijkasemwat K., 2017, Using  leucaena to improve the quality of pineapple 
plant silage, Chemical Engineering Transactions, 58, 847-852  DOI: 10.3303/CET1758142 

847



appropriate knowledge for farmer to increase farmers’ incomes. Suchat et al. (2011) was to determine the 
effect of ensiled pineapple waste compared with pangola hay as roughage source on rumen fermentation and 
feed utilization of native cattle. The apparent digestibility of dry matter, organic matter, crude protein, NDF and 
ADF in cattle fed only pineapple waste as roughage source was higher than in cattle fed only pangola hay. 
The pineapple waste have several benefit in terms of increasing caloric density, digestibility and feed 
utilization as compared to pangola hay. Moreover, it also enhances populations of dominant cellulolytic 
bacteria in the rumen.  
The chemical composition of the pineapple plant is high in fibre which makes it is a good source of fibre for 
ruminant feed.  Pine apple plants could be used as ruminant feed in silage forms to preserves the quality of its 
nutrient (Sayan, 2004). Furthermore, it can be kept for a long time. Pineapple plant silage can alleviate a mal-
nutrition in ruminants during the dry season or flooding time. It is a high quality silage because it is good in 
digestibility and palatability. It is easy for animal raisers to make pineapple plant silage for their animals by 
themselves. This can help reduces animal feed cost and increase the quality of feed which is reflected in the 
high production performance of their animal. However, the quality of silage is depends on feed additive uses 
during the making processes. This research is aimed at selecting the suitability of leucaena level to apply to 
pineapple plant silage making for ruminant feed.  

2. Materials and Method 

2.1  Silage preparation  

The harvested material was 3 samples of para grass, leucaena and pineapple plants randomly taken and 
chopped to 2-3 cm. (Figure 1) The pre-silage material samples were  5 treatments as follows:- 1. pineapple 
plant 100%, 2. pine apple plant mixed with leucaena 5%, 3. pine apple plant mixed with leucaena 10%, 4. pine 
apple plant mixed with leucaena 15% and 5. grass 100%. All treatments were put into 1%NaCL2 and tightly 
sealed in plastic containers. They were stored at room temperature for 21 days. A total of 25 g sample was 
dissolved in 100 ml sterile water and stirred for 10 min. The pH values were measured for acidity changes 
using the pH meter   (Polan et al., 1998). After 21 days fermentation, the color and aroma of the silages were 
evaluated according to the indices score of Muhammad et al. (2008). For the color description the silage was 
scored as 1 = dark brown, 2 = light brown, 3 = pale yellow and 4 = yellowish green. For the aroma description 
the silage was scored as 1 = putrid or rancid, 2 = pleasant, 3 = sweet and 4 = very sweet.  
 

Figure 1  The Fresh samples of pineapple plant 

2.2  Proximate composition analysis of silage    

Fresh samples of 1,000 g were randomly by collected to determine nutrient composition. The samples were 
done by oven drying at 60o C for 48 h prior to proximate analysis. Dry matter (DM), ash, crude protein (CP), 
crude fibre (CF), ether extract (EE), nitrogen free extract (NFE) and organic matter (OM) were determined 
according to the methods of AOAC (1995). Neutral detergent fibre (NDF) and Acid detergent fibre (ADF) were 
determined according to the method of Van Soest and Robertson (1979). Proximate analysis was done before 
and after fermentation. The experiment was repeated two times. Data were then computed using analysis of 
variance and treatment means were compared with Duncan’s Multiple Range Test (DMRT)  at P = 0.05 and P 
= 0.01.  

848



3. Results 

3.1  Physical characteristic of silage 
After 21 days of ensilage, the plastic containers were opened and examined for gross characteristics. The 
physical characteristic (Table 1.) showed that the color of treatment 1 was a yellowish green color which was a 
good characteristic of silage (Figure 2). For treatment 2,.3 and 4 they were light brown color. Treatment 5 was 
a dark brown color, with quality being lower than treatment 1, 2, 3 and 4 (Muhammad et al., 2008). Generally, 
the silage should have a darker color than fresh forage because the color of chlorophyll reacted with acid from 
fermentation. These changed them to become a magnesium free pigment phaeophytin. However, the 
carotene was a provitamin A which was suffered from oxidation at high temperature (Azim et al.,2000 ; 
Wanapat, 1986). The aroma of silage treatment 1, 2, 3 and 4 were aromatic and acidic like pickled fruit (sweet 
smell). The sweet smell was caused by lactic acid bacteria which utilized sugar in the forage to produce lactic 
acid and volatile acid (McDonald et al.,1991; Merry et al., 2000). For treatment 5  the aroma of silage was very 
sour and may have occurred by the activity of proteolytic bacteria change protein to ammonia, volatile acid, 
amine and amide which dissatisfied in silage (Sayan, 2004). The pH values of silage treatment 1, 2, 3, 4 and 5 
were 3.45, 3.43, 3.72, 3.52 and 4.27 respectively. Overall, treatments  showed highly significant differences at 
a low level (P < 0.01). The pH values of silage was indicated that bacteria to produced lactic acid (Schroeder, 
2004). The pH of good quality silage was 3.5 – 4.5, if pH increases more than 5.1 it was low quality (church, 
1991). The moisture value of silage showed that highly significant differences (P < 0.01). Treatment 1 gave 
significantly higher moisture (81.83%) than treatment 4 (80.95%), treatment 2 (79.77%), treatment 3 (79.10%) 
and was lower in treatment 5 (72.93%). The silage making had high moisture and lowered dry matter during 
raining season may have coursed risk for the silage to spoil. In cases where the silage had lower  moisture 
and higher of dry matter it  may have been more fibre difficult to compact the silage in the  silo ( Saranya W. 
and Jantakarn, A., 1997).       

Table 1   The Physical Characteristics of Silage 

silage 
character 
Colour of silage Aroma of silage 

1 Pineapple plant 100%        Yellowish green Aromatic and acidic 
2  Pineapple plant mixed with leucaena 5%, Light brown Aromatic and acidic 
3 Pineapple plant mixed with leucaena 10%, Light brown Aromatic and acidic 
4 Pineapple plant mixed with leucaena 15%, Light brown Aromatic and acidic 
5 Grass silage 100% Dark brown      Very sour 

 

 

Figure 2 The physical characteristics of  pineapple plant silage 

849



3.2  Nutritive values of silage 

The proximate composition of the examined silage is  shown in Table 2. Results revealed that highly 
significant differences (P < 0.01). Treatment 5 gave significantly higher dry matter (27.08%) than treatment 3 
(20.90%), treatment 2 (20.23%), treatment 4 (19.05%) and was lower in treatment 1 (18.17%). For the good 
fermentation process and fast originate, dry matter had  a loss of approximately 1 – 2 % from respiratory of 
forage during first stage (McDonald et al., 1991). The value of ash showed that Treatment 5 gave significantly 
higher ash (16.02%) than treatment 3 (9.71%), treatment 1 (9.38%), treatment 2 and lower ash in treatment 4 
respectively. The increased of ash occurred by the utilization of plant organic substance and change to 
inorganic substance by microorganism during fermentation (Frame, 1994). The calcium value of silage 
showed that treatment 4 gave significantly higher calcium (0.48%) than treatment 3 (0.35%), treatment 5 
(0.34%), Treatment 2 (0.32%) and lower calcium in treatment 1 (0.26%) respectively. For the phosphorus 
treatment 1 gave significantly higher phosphorus (0.38%) than treatment 4 (0.36%), treatment 2-3 (0.29%) 
and lower phosphorus in treatment 5 (0.19%) respectively. Treatment 4 gave significantly higher protein 
(8.19%) than treatment 5 (7.39%), treatment 3 (6.99%), treatment 2 (6.39%) and lower in treatment 1 (6.13%) 
respectively. Leucaena had condensed tannin  4 – 6 % of dry matter which could be caught protein and 
protect the digestion by microorganisms. McDonald et al. (1991) reported that usually decreases in protein 
was due to  the initially digestion by microorganism, while the increased of protein may occurs by the influence 
of salt, which it prevents clostridium sp. to not destroy protein. There were not significantly differences in 
protein, ether extract, calcium, and phosphorus.  Pineapple plant mixed with leucaena 5% gave significantly 
lower fibre (21.76%) than pineapple plant mixed with leucaena 10% (22.51%), pineapple plant mixed with 
leucaena 15% (23.15), pineapple plant 100% (24.18%) and  grass silage 100% respectively, but it was not 
significantly different in the pineapple plant mixed with leucaena. However, fibre decreased during 
fermentation which may occurred have happened due to lactobacillus sp. which could have digested the cell 
wall (Mc Donald et al., 1991)  

Table 2  Proximate composition analysis of pine apple plant silage.    

Treatment 
Nutritive value of pine apple plant silage 

pH Moist. DM Ash CP CF Ca P Energy 

1 3.45d 81.83
a 18.17c 9.38b 6.13d 24.18ab 0.26c 0.38a 3,620.99a 

2 3.43c 
79.77ab 

20.23bc 9.05bc 6.39cd 21.76c 0.32b 0.29b 3,471.06b 

3 3.72b 79.10
b 20.90b 9.71b 6.99bc 22.51c 0.35b 0.29b 3,475.86b 

4 3.52c 80.95
ab 19.05bc 8.14c 8.19a 23.15bc 0.48a 0.36a 3,697.17a 

5 4.27a 
72.93c 

27.08a 16.02a 7.39b 25.42ab 0.34b 0.19c 3,029.80c 

Means followed by a common letter in each column are not significantly different (p<0.01)  

Results showed that fibre analysis by using Van Soest demonstrated the fibre digestion of pineapple plants 
mixed with leucaena silage could be degraded (Table 3). Pineapple plant mixed with leucaena 15% gave 
significantly lower  NDF (42.19%) than pineapple plant mixed with leucaena 5% (43.30%), pineapple plant 
mixed with leucaena 10% (43.71%), pineapple plant 100% (47.10%) and grass silage 100% (48.76%), but it 
was not significantly different in pineapple plant mixed with leucaena. For NDF the decreased in may be due 
to the part of cell wall  and carbohydrate structure being utilized as an energy source for microorganism 
growth during fermentation (O’Kiely and Muck, 1998). Pineapple plant mixed with leucaena 5% gave 
significantly lower ADF (29.85)  than grass silage 100% (29.88%), pineapple plant mixed with leucaena 15% 
(30.46%), pineapple plant mixed with leucaena 10% (30.90%) and pineapple plant 100% (31.94%) 
respectively. The acid detergent fibre of silage trend were perhaps increased by the sugar structured in the 
plant cell with the microorganism being utilized and causing ADF increase (Campbell and Bruchanan-Smith, 
1991). Generally, a good range of ADF in dairy cattle’ feed should be around 40 – 60 % to produces butterfat 
in milk (Somjit, 2006; Jantakarn, 2009). Grass silage 100% gave significantly lower ADL (3.98%) than 
pineapple plant mixed with leucaena 15% (5.66%), pineapple plant mixed with leucaena 5% (5.99%), 
pineapple plant 100% (6.19%) and pineapple plant mixed with leucaena 10% (6.23%) respectively. It was not 
significantly different in ADL of pineapple plant 100% and pineapple plant mixed with leucaena. The quantity 
of lignin, cellulose, and hemicellulose in feed are important for  the forage crop of ruminants. A good quality of 

850



forage crop should be low in lignin (Flores, 1991). In this study, pineapple plant mixed with leucaena 15% 
gave significantly higher metabolizable energy (3,697.17 kcal/k) than pineapple plant 100% (3,620.99 kcal/k), 
pineapple plant mixed with leucaena 10% (3,475.86 kcal/k), pineapple plant mixed with leucaena 5% 
(3,471.06 kcal/k) and grass silage 100% (3,029.80 kcal/k) respectively. The leucaena was completed in 
nutrient and when mixed with the pineapple plant the metabolizable energy was increased (Piliwan et al., 
1989).    

Table 3  Fibre analysis of pineapple plant silage. 

Treatment NDF ADF ADL 

1 47.10a 31.94a 6.19a 

2 43.30b 29.85b 5.99a 

3 43.71b 30.90ab 6.23a 

4 42.91b 30.46ab 5.66a 

5 48.76a 29.88b 3.98b 

Means followed by a common letter in each column are not significantly different (p<0.01)  
 
Treatment 1. = pineapple plant 100%   
Treatment 2. = pine apple plant mixed with leucaena 5% 
Treatment 3. = pine apple plant mixed with leucaena 10%  
Treatment 4. = pine apple plant mixed with leucaena 15%   
Treatment 5. = grass 100%. 

4. Conclusion   

The uses of leucaena to improve   nutritive value in pineapple plant silage were determined.  This study was to 
improve the quality of pineapple plant silage by leucaena supplementation for using as roughage during the 
shortage of green forages. There were 5 treatments as follows:- 1. pineapple plant 100%, 2. pineapple plant 
mixed with leucaena 5%, 3. pineapple plant mixed with leucaena 10%, 4. pineapple plant mixed with leucaena 
15% and 5. grass 100%. The silage samples were mixed with NaCl2

 all formula and kept tightly sealed in 
plastic containers and stored at room temperature for 21 days. The results of physical characteristics, 
chemical composition and fibre analysis of  pineapple plant silage were indicated that the color appearance    
of formula 1 was yellowish green color, formula 2,3,4 were light brown color and formula 5 dark brown color.             
The aroma of the pineapple plant silage was aromatic and acidic like pickled fruit. The chemical composition 
analysis of silage found that highly significantly difference (p< 0.01). Which this pH value in rang 3.43 – 4.27, 
Dry matter 18.17 – 27.08%, ash 8.14 – 16.02%, protein 6.13 -8.19%, fibre 21.76 – 25.42, NDF 42.91 – 48.76,  
ADF 29.85 – 31.94, lignin 3.98 – 6.23, Ca 0.26 – 0.48, P 0.20 – 0.38 and energy 3,029.80 – 3,697.17. 
Pineapple plant silage mixed with leucaena could  improve the quality of nutritive value for ruminants.    
 
References 

AOAC (Association of Official Analytical Chemists)., 1995, Official Methods of Analysis of the Association of 
Official Analytical Chemists, 16th ed. Washington D.C.  

Azim  A., Khan  A. G., Nadeem  M. A., Muhammad  D,  2000, “Influence of maize and cowpea intercropping 
on fodder production and characteristics of silage,” Asian Aust. J. Anim. Sci., 3 : 781-784. 

Campbell  C.P.,  Buchanan – Smith  J.G., 1991, Effect of alfalfa grass silage dry matter content on ruminal 
digestion and milk production in lactating dairy cows, Canadian  Journal of Animal Science, 71(2) : 457 – 
467.  

Church D. C., 1991, Livestock Feeds and Feeding, Prentice Hall International, inc., USA., 540 P.   
Flores  D. A., 1991, “Biotechnology and the improvement of silage (tropical and temperate) rumen digestion : 

a mini-review,” Appl. Microbiol. Biotech. 35 : 277-281. 
Frame J, 1994, Soil fertility and grass production; nitrogen. In : Frame J., (ed.), Improved Grassland 

Management  Farming,  Press Book, Redwood Press, Melksham, Wiltshire, UK. 

851



Gowda N.K., Vallesha N.C., Awachat V.B., Anandan S., Pal D.T., Prasad C.S., 2015, Study on evaluation of 
silage from pineapple (Ananas comosus) fruit residue as livestock feed, Trop. Anim. Health. Prod., 47 (3) : 
557 – 61. 

Jantakarn  Arannanant, 2009, Fibre starch and sugar in forage crop, Journal of  forage crop, 14 : 4-6. 
McDonald P., Henderson N., Herson S., 1991, The biochemistry of silage, 2nd ed. United Kingdom : 

Chalcombe. 
Metha  Wanapat, 1986, Ruminant Nutrition, Department of Animal Husbandry, Faculty of Agriculture, Khonkan 

University, 317 P. 
Merry  R. J., Jones, R., Theodorou  M. K., 2000, The conservation of grass, pp. 196-228. In Hopkins,  A., 

(Ed.), Grass its production and utilization, 3 rd. ed. United Kingdom : Blackwell Science.  
Muhammad I. R., Baba M., Mustapha  A., Ahmad M. Y., Abdurrahman L. S., 2008, “Use of legume in the 

improvement of silage quality of columbus grass (Sorghum almum Parodi),” Res. J. Anim. Sci. 2 : 109-112. 
O’Kiely P., Muck R.W., 1998, Grass silage, In Grass for dairy cows (eds. J.H. and D.J.R. Cherneg), CABI 

publication, P 223 – 251.  
Piliwan  P., Valaikan J.,  Nataya S., 1989, Analysis of Feed Stuff and Serum, Section of Feed Stuff Analysis, 

Division of Animal Feed, Department of Livestock Development, 48 P.  
Polan C. E.., Stieve D. E., Grrett J. L., 1998, “Protein preservation and ruminal degradation of ensiled forage 

treated with heat, formic acid, ammonia or microbial inoculants,” J. Dairy Sci., 81 : 765-776. 
Prachya P.,Pensiri S., Chinda S., 2001, Use of Pineapple leaves in Total Mixed Ration for Lactating Cows, 

Annual Research Report. Bureau of Animal Nutrition Development, Department of Livestock Development, 
Ministry of Agriculture and Cooperative, 257 – 268. 

Saranya w., Jantakarn A., 1997, Quality Evaluation of Silage in Plastic Bag with Additives, in Research Project 
No. 37-0713-098, Animal Nutrition Laboratory section, Division of Animal Nutrition, Department of 
Livestock Development, P 203 – 210. 

Sayan Tudsri, 2004, Tropical Forage crop, Kasetsart University, Bangkok.534 P. 
Schroeder  J.W., 2004, Silage Fermentation and Preservation, North Dakota State University, USA., 8 P. 
Somjit Tanomvongvatana, 2006, Study on silage quality for dairy cows, PhD. Dissertation, Division of 

biotechnology graduate college, Kasetsart University, Bangkok. 
Suchart S., Chalong W., Yanin O., 2011, Effects of levels of ensiled pineapple waste and pangola hay fed as 

roughage sources on feed intake, nutrient digestibility and ruminal fermentation of Southern Thai native 
cattle, Songklanakarin J. Sci.Technol. 33 (3), 281 – 289. 

Van Soest P. J.,  Robertson J. B., 1979, Systems of analysis for evaluating fibrous feeds, pp.49-60. In Pgden, 
W. J., Balch C. C. Graham  M., (Eds.), Procedures of standardization of analytical  methodology for feeds, 
Canada : IDRC. 

Warunee P.,  Walaikhan J., 1998, Collection and improvement in Nutritive Value Database of feed stuffs, 
Bureau of Animal Nutrition Development, Department of Livestock Development, Ministry of Agriculture 
and Cooperative. 40 P. 

 

852